GARbro-mirror/ArcFormats/ImageWBM.cs

1008 lines
35 KiB
C#

//! \file ImageWBM.cs
//! \date Thu Jul 09 20:59:09 2015
//! \brief Wild Bug's image format.
//
// Copyright (C) 2015 by morkt
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to
// deal in the Software without restriction, including without limitation the
// rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
// sell copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
// FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
// IN THE SOFTWARE.
//
using System;
using System.ComponentModel.Composition;
using System.IO;
using System.Windows.Media;
using System.Windows.Media.Imaging;
using GameRes.Utility;
namespace GameRes.Formats.WildBug
{
internal class WbmMetaData : ImageMetaData
{
public int EntryCount;
public int EntrySize;
public byte[] Header;
}
internal class WpxSection
{
public int DataFormat;
public int Offset;
public int UnpackedSize;
public int PackedSize;
public static WpxSection Find (byte[] header, byte id, int count, int dir_size)
{
int ptr = 0;
int n = 0;
while (header[ptr] != id)
{
ptr += dir_size;
if (ptr >= header.Length)
return null;
if (++n >= count)
return null;
}
return new WpxSection {
DataFormat = header[ptr+1],
Offset = LittleEndian.ToInt32 (header, ptr+4),
UnpackedSize = LittleEndian.ToInt32 (header, ptr+8),
PackedSize = LittleEndian.ToInt32 (header, ptr+12),
};
}
}
[Export(typeof(ImageFormat))]
public class WbmFormat : ImageFormat
{
public override string Tag { get { return "WBM"; } }
public override string Description { get { return "Wild Bug's image format"; } }
public override uint Signature { get { return 0x1A585057; } } // 'WPX'
public override ImageMetaData ReadMetaData (Stream stream)
{
byte[] header = new byte[0x10];
if (header.Length != stream.Read (header, 0, header.Length))
return null;
if (!Binary.AsciiEqual (header, 4, "BMP"))
return null;
int count = header[0xE];
int dir_size = header[0xF];
if (1 != header[0xC] || 0 == count || 0 == dir_size)
return null;
header = new byte[count * dir_size];
if (header.Length != stream.Read (header, 0, header.Length))
return null;
var section = WpxSection.Find (header, 0x10, count, dir_size);
if (null == section)
return null;
if (section.UnpackedSize < 0x10)
return null;
stream.Seek (section.Offset, SeekOrigin.Begin);
byte[] data = new byte[section.UnpackedSize];
if (data.Length != stream.Read (data, 0, data.Length))
return null;
return new WbmMetaData
{
Width = LittleEndian.ToUInt16 (data, 4),
Height = LittleEndian.ToUInt16 (data, 6),
BPP = data[0xC],
EntryCount = count,
EntrySize = dir_size,
Header = header,
};
}
public override ImageData Read (Stream stream, ImageMetaData info)
{
var meta = info as WbmMetaData;
if (null == meta)
throw new ArgumentException ("WbmFormat.Read should be supplied with WbmMetaData", "info");
var section = WpxSection.Find (meta.Header, 0x11, meta.EntryCount, meta.EntrySize);
if (null == section)
throw new InvalidFormatException();
PixelFormat format;
int pixel_size;
switch (meta.BPP)
{
case 24:
format = PixelFormats.Bgr24;
pixel_size = 3;
break;
case 32:
format = PixelFormats.Bgr32;
pixel_size = 4;
break;
case 16:
format = PixelFormats.Bgr555;
pixel_size = 2;
break;
default:
throw new NotSupportedException ("Not supported WBM bitdepth");
}
int stride = ((int)meta.Width * pixel_size + 3) & -4;
var reader = new WbmReader (stream, section);
var pixels = reader.Unpack (stride, pixel_size, section.DataFormat);
if (null == pixels)
throw new InvalidFormatException();
if (meta.BPP < 24)
return ImageData.Create (info, format, null, pixels, stride);
section = WpxSection.Find (meta.Header, 0x13, meta.EntryCount, meta.EntrySize);
if (null == section)
return ImageData.Create (info, format, null, pixels, stride);
int alpha_stride = ((int)meta.Width + 3) & -4;
byte[] alpha = null;
try
{
reader = new WbmReader (stream, section);
alpha = reader.Unpack (alpha_stride, 1, section.DataFormat);
}
catch { }
if (null == alpha)
return ImageData.Create (info, format, null, pixels, stride);
byte[] alpha_image = new byte[4*meta.Width*meta.Height];
int dst = 0;
for (int y = 0; y < meta.Height; ++y)
{
int alpha_src = y * alpha_stride;
int src = y * stride;
for (int x = 0; x < meta.Width; ++x)
{
alpha_image[dst++] = pixels[src];
alpha_image[dst++] = pixels[src+1];
alpha_image[dst++] = pixels[src+2];
alpha_image[dst++] = alpha[alpha_src+x];
src += pixel_size;
}
}
return ImageData.Create (info, PixelFormats.Bgra32, null, alpha_image, (int)meta.Width*4);
}
public override void Write (Stream file, ImageData image)
{
throw new System.NotImplementedException ("WbmFormat.Write not implemented");
}
}
internal class WbmReader
{
Stream m_input;
byte[] m_output;
int m_packed_size;
int m_start_pos;
public byte[] Data { get { return m_output; } }
public WbmReader (Stream input, WpxSection section)
{
m_input = input;
m_start_pos = section.Offset;
m_output = new byte[section.UnpackedSize];
m_packed_size = section.PackedSize;
}
void GenerateOffsetTableV1 (int[] offset_table, int stride, int pixel_size)
{
offset_table[4] = pixel_size;
offset_table[2] = 2 * pixel_size;
offset_table[5] = 3 * pixel_size;
if (5 * pixel_size < stride)
{
offset_table[6] = stride - pixel_size;
offset_table[0] = stride;
offset_table[7] = pixel_size + stride;
offset_table[3] = 2 * pixel_size + stride;
offset_table[1] = 2 * stride;
}
else
{
offset_table[6] = 4 * pixel_size;
offset_table[0] = 5 * pixel_size;
offset_table[7] = 6 * pixel_size;
offset_table[3] = 7 * pixel_size;
offset_table[1] = 8 * pixel_size;
}
}
void GenerateOffsetTableV2 (int[] offset_table, int stride, int pixel_size)
{
offset_table[0] = pixel_size;
offset_table[1] = 2 * pixel_size;
offset_table[2] = 3 * pixel_size;
if (5 * pixel_size < stride)
{
offset_table[3] = stride - pixel_size;
offset_table[4] = stride;
offset_table[5] = pixel_size + stride;
offset_table[6] = 2 * pixel_size + stride;
offset_table[7] = 2 * stride;
}
else
{
offset_table[3] = 4 * pixel_size;
offset_table[4] = 5 * pixel_size;
offset_table[5] = 6 * pixel_size;
offset_table[6] = 7 * pixel_size;
offset_table[7] = 8 * pixel_size;
}
}
int m_condition;
public byte[] Unpack (int stride, int pixel_size, int flags) // sub_40919C
{
int[] offset_table = new int[8];
GenerateOffsetTableV2 (offset_table, stride, pixel_size);
for (m_condition = 1; m_condition >= 0; --m_condition)
{
try
{
ResetInput();
if (0 == (flags & 0x80) && 0 != m_packed_size)
{
byte[] ref_table = new byte[0x10000];
if (0 != (flags & 1))
{
if (0 != (flags & 8))
{
if (0 != (flags & 4))
return UnpackVD (ref_table, offset_table, pixel_size);
else if (0 != (flags & 2))
return UnpackVB (ref_table, offset_table, pixel_size);
else
return UnpackV9 (offset_table, pixel_size);
}
else if (0 != (flags & 4))
return UnpackV5 (ref_table, offset_table, pixel_size);
else if (0 != (flags & 2))
return UnpackV3 (ref_table, offset_table, pixel_size);
else
return UnpackV1 (offset_table, pixel_size);
}
else if (0 != (flags & 4))
return UnpackV4 (ref_table, offset_table, pixel_size);
else if (0 != (flags & 2))
return UnpackV2 (ref_table, offset_table, pixel_size);
else
return UnpackV0 (offset_table, pixel_size);
}
else if (m_output.Length == m_input.Read (m_output, 0, m_output.Length))
return m_output;
}
catch
{
if (0 == m_condition)
throw;
}
GenerateOffsetTableV1 (offset_table, stride, pixel_size);
}
return null;
}
byte[] UnpackVD (byte[] a4, int[] offset_table, int pixel_size) // 0x0F format
// int sub_460470(void *dst, const void *src, unsigned __int8 *ref_table, unsigned int packed_size, int *offset_table, int unpacked_size, unsigned int pixel_size)
{
byte[] v47 = BuildTable(); //sub_46C26C();
int min_count = 1 == pixel_size ? 2 : 1;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step + 0x80)
return null;
int v7 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v7 + 128;
if (!FillRefTable (a4, pixel_size + v7))
return null;
int v45 = 16384;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
int v24 = 0;
int v25 = 0;
v45 &= ~0xff00;
v45 |= m_output[dst - pixel_size] << 8;
int v26 = 16384;
for (;;)
{
v24 = (v24 + 1) & 0xFF;
if (GetNextBit() != 0)
v25 |= v26;
if (a4[2 * v25] == v24)
break;
v26 >>= 1;
if (0 == v26)
return null;
}
v24 = a4[2 * v25 + 1];
byte v28 = v47[v45 + v24];
if (0 != v24)
{
Buffer.BlockCopy (v47, v45, v47, v45+1, v24);
v47[v45] = v28;
}
m_output[dst++] = v28;
--remaining;
if (0 == remaining)
return m_output;
}
int count;
int src_offset;
if (GetNextBit() != 0)
{
int v37 = ReadNext();
count = 2;
src_offset = dst - 1 - v37;
}
else
{
count = min_count;
int v36 = GetNextBit() << 2;
v36 |= GetNextBit() << 1;
v36 |= GetNextBit();
src_offset = dst - offset_table[v36];
}
if (0 == GetNextBit())
{
count += ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackVB (byte[] a4, int[] offset_table, int pixel_size) // 0x0B format
{
byte[] v47 = BuildTable(); //sub_46C26C();
int min_count = 1 == pixel_size ? 2 : 1;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step + 0x80)
return null;
int v7 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v7 + 128;
if (!FillRefTable (a4, pixel_size + v7))
return null;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
int v24 = 0;
int v25 = 0;
int v26 = 16384;
for (;;)
{
v24 = (v24 + 1) & 0xFF;
if (GetNextBit() != 0)
v25 |= v26;
if (a4[2 * v25] == v24)
break;
v26 >>= 1;
if (0 == v26)
return null;
}
m_output[dst++] = a4[2 * v25 + 1];
--remaining;
if (0 == remaining)
return m_output;
}
int count;
int src_offset;
if (GetNextBit() != 0)
{
int v37 = ReadNext();
count = 2;
src_offset = dst - 1 - v37;
}
else
{
count = min_count;
int v36 = GetNextBit() << 2;
v36 |= GetNextBit() << 1;
v36 |= GetNextBit();
src_offset = dst - offset_table[v36];
}
if (0 == GetNextBit())
{
count += ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV9 (int[] offset_table, int pixel_size) // 0x09 format
{
throw new NotImplementedException();
}
byte[] UnpackV5 (byte[] a4, int[] offset_table, int pixel_size) // 0x07 format
// int sub_409AF4 (void *a1, FILE *stream, void *ptr, void *a4, unsigned int m_packed_size, int *offset_table, int unpacked_size, unsigned int pixel_size)
{
byte[] v46 = BuildTable();
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step + 0x80)
return null;
int v10 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v10 + 128;
if (!FillRefTable (a4, pixel_size + v10))
return null;
int v43 = 16384;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
int v25 = 0;
int v26 = 0;
v43 &= ~0xff00;
v43 |= m_output[dst-pixel_size] << 8;
int v27 = 16384;
for (;;)
{
v25 = (v25 + 1) & 0xff;
if (GetNextBit() != 0)
v26 |= v27;
if (a4[2 * v26] == v25)
break;
v27 >>= 1;
if (0 == v27)
return null;
}
v25 = a4[2 * v26 + 1];
byte v29 = v46[v43 + v25];
if (0 != v25)
{
Buffer.BlockCopy (v46, v43, v46, v43+1, v25);
v46[v43] = v29;
}
m_output[dst++] = v29;
--remaining;
if (0 == remaining)
return m_output;
}
int src_offset;
int count;
if (GetNextBit() != 0)
{
count = min_count;
int v32 = GetNextBit() << 2;
v32 |= GetNextBit() << 1;
v32 |= GetNextBit();
src_offset = dst - offset_table[v32];
}
else
{
byte v35 = ReadNext();
count = 2;
src_offset = dst - 1 - v35;
}
if (0 == GetNextBit())
{
count += ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV4 (byte[] a4, int[] offset_table, int pixel_size) // 0x06 format
// signed int __cdecl sub_40B044(void *a1, FILE *stream, void *ptr, void *a4, unsigned int packed_size, int *offset_table, int unpacked_size, unsigned int pixel_size)
{
byte[] v48 = BuildTable();
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 4) & -4;
if (m_available < step + 0x80)
return null;
int v10 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v10 + 128;
if (!FillRefTable (a4, pixel_size + v10))
return null;
int v46 = 16384;
while (remaining > 0)
{
int v28;
while (0 == (GetNextBit() ^ m_condition))
{
int v27 = 0;
v28 = 0;
v46 &= ~0xff00;
v46 |= m_output[dst - pixel_size] << 8;
int v29 = 16384;
for (;;)
{
v27 = (v27 + 1) & 0xff;
if (GetNextBit() != 0)
v28 |= v29;
if (a4[2 * v28] == v27)
break;
v29 >>= 1;
if (0 == v29)
return null;
}
v27 = a4[2 * v28 + 1];
byte v31 = v48[v46 + v27];
if (0 != v27)
{
Buffer.BlockCopy (v48, v46, v48, v46+1, v27);
v48[v46] = v31;
}
m_output[dst++] = v31;
--remaining;
if (0 == remaining)
return m_output;
}
v28 = GetNextBit() << 1;
v28 |= GetNextBit();
v28 <<= 1;
v28 |= GetNextBit();
int src_offset = dst - offset_table[v28];
int count;
if (GetNextBit() != 0)
{
count = min_count;
}
else
{
count = min_count + ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV3 (byte[] a4, int[] offset_table, int pixel_size) // 0x03 format
// int sub_409F70(void *a1, FILE *stream, void *ptr, void *a4, unsigned int packed_size, int *offset_table, int unpacked_size, unsigned int pixel_size)
{
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step + 0x80)
return null;
int v9 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v9 + 128;
if (!FillRefTable (a4, pixel_size + v9))
return null;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
int v24 = 0;
int v25 = 0;
int v26 = 16384;
for (;;)
{
++v24;
if (GetNextBit() != 0)
v25 |= v26;
if (a4[2 * v25] == v24)
break;
v26 >>= 1;
if (0 == v26)
return null;
}
m_output[dst++] = a4[2 * v25 + 1];
--remaining;
if (0 == remaining)
return m_output;
}
int count, src_offset;
if (GetNextBit() != 0)
{
count = min_count;
int v28 = GetNextBit() << 1;
v28 |= GetNextBit();
v28 <<= 1;
v28 |= GetNextBit();
src_offset = dst - offset_table[v28];
}
else
{
count = 2;
src_offset = dst - 1 - ReadNext();
}
if (GetNextBit() == 0)
{
count += ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV2 (byte[] a4, int[] offset_table, int pixel_size) // 0x02 format
// int sub_40B458(void *a1, FILE *stream, unsigned __int8 *ptr, void *a4, unsigned int packed_size, int *offset_table, int unpacked_size, unsigned int a8)
{
byte[] v48 = BuildTable();
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step + 0x80)
return null;
int v9 = -pixel_size & 3;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + v9 + 128; // within m_buffer
if (!FillRefTable (a4, pixel_size + v9))
return null;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
int v20 = 0;
int v21 = 0;
v9 = 16384;
for (;;)
{
++v20;
if (0 != GetNextBit())
v21 |= v9;
if (a4[2 * v21] == v20)
break;
v9 >>= 1;
if (0 == v9)
return null;
}
m_output[dst++] = a4[2 * v21 + 1];
--remaining;
if (0 == remaining)
return m_output;
}
int v22 = GetNextBit() << 1;
v22 |= GetNextBit();
v22 <<= 1;
v22 |= GetNextBit();
int src_offset = dst - offset_table[v22];
int count;
if (0 != GetNextBit())
{
count = min_count;
}
else
{
count = min_count + ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV1 (int[] offset_table, int pixel_size) // 0x01 format
//int sub_40A3C4(void *a1, FILE *stream, const void *ptr, unsigned int packed_size, int *offset_table, int unpacked_size, unsigned int pixel_size)
{
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step)
return null;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + (-pixel_size & 3);
m_bits = m_buffer[m_current++];
m_bit_count = 8;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
m_output[dst++] = ReadNext();
--remaining;
if (0 == remaining)
return m_output;
}
int count, src_offset;
if (GetNextBit() != 0)
{
count = min_count;
int v14 = GetNextBit() << 2;
v14 |= GetNextBit() << 1;
v14 |= GetNextBit();
src_offset = dst - offset_table[v14];
}
else
{
count = 2;
src_offset = dst - 1 - ReadNext();
}
if (GetNextBit() == 0)
{
count += ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
byte[] UnpackV0 (int[] offset_table, int pixel_size) // 0x00 format
// int sub_40B83C(void *a1, FILE *stream, const void *ptr, unsigned int packed_size, int *a5, int unpacked_size, unsigned int pixel_size)
{
int min_count = 1 == pixel_size ? 2 : 1;
if (0 == m_packed_size)
return null;
m_available = FillBuffer();
if (0 == m_available)
return null;
int step = (pixel_size + 3) & -4;
if (m_available < step)
return null;
Buffer.BlockCopy (m_buffer, 0, m_output, 0, pixel_size);
int dst = pixel_size;
int remaining = m_output.Length - pixel_size;
m_current = pixel_size + (-pixel_size & 3);
m_bits = m_buffer[m_current++];
m_bit_count = 8;
while (remaining > 0)
{
while (0 == (GetNextBit() ^ m_condition))
{
m_output[dst++] = ReadNext();
--remaining;
if (0 == remaining)
return m_output;
}
int v14 = GetNextBit() << 1;
v14 |= GetNextBit();
v14 <<= 1;
v14 |= GetNextBit();
int src_offset = dst - offset_table[v14];
int count;
if (GetNextBit() != 0)
{
count = min_count;
}
else
{
count = min_count + ReadCount();
}
if (remaining < count)
return null;
Binary.CopyOverlapped (m_output, src_offset, dst, count);
dst += count;
remaining -= count;
}
return m_output;
}
int ReadCount ()
{
int n = 1;
while (0 == GetNextBit())
{
++n;
}
int count = 1;
for (int i = 0; i < n; ++i)
{
count += count + GetNextBit();
}
return count - 1;
}
static byte[] BuildTable () // sub_4090E0
{
var table = new byte[0x100*0x100];
for (int i = 0; i < 0x100; ++i)
{
byte v2 = (byte)(-1 - i);
for (int j = 0; j < 0x100; ++j)
{
table[0x100*i + j] = v2--;
}
}
return table;
}
byte[] m_buffer = new byte[0x8000];
int m_current = 0;
int m_available = 0;
byte ReadNext ()
{
if (m_current >= m_available)
{
m_available = FillBuffer();
if (0 == m_available)
throw new InvalidFormatException ("Unexpected end of file");
m_current = 0;
}
return m_buffer[m_current++];
}
int m_input_remaining;
void ResetInput ()
{
m_input.Position = m_start_pos;
m_input_remaining = m_packed_size;
}
int FillBuffer () // sub_409B02
{
int read = 0;
if (m_input_remaining > 0)
{
int size = Math.Min (m_input_remaining, 0x8000);
m_input_remaining -= size;
read = m_input.Read (m_buffer, 0, size);
}
return read;
}
byte m_bits;
int m_bit_count = 0;
int GetNextBit ()
{
if (0 == m_bit_count)
{
m_bits = ReadNext();
m_bit_count = 8;
}
int bit = m_bits >> 7;
m_bits <<= 1;
--m_bit_count;
return bit;
}
bool FillRefTable (byte[] table, int src)
{
m_bits = m_buffer[m_current++];
m_bit_count = 8;
for (int n = 0; n < 0x100; )
{
byte v16 = m_buffer[src++];
for (int half = 0; half < 2; ++half)
{
byte v17 = (byte)(v16 & 0xF);
if (0 != v17)
{
int v18 = 0;
for (int i = v17; i != 0; --i)
{
if (0 == m_bit_count)
{
if (m_current >= m_available)
return false;
m_bits = m_buffer[m_current++];
m_bit_count = 8;
}
int bit = m_bits >> 7;
m_bits <<= 1;
--m_bit_count;
v18 += v18 + bit;
}
if (15 != v17)
v18 <<= 15 - v17;
table[2 * v18] = v17;
table[2 * v18 + 1] = (byte)n;
}
++n;
v16 >>= 4;
}
}
return true;
}
}
}